Arctic Methane Alarm

Originally posted by Sam Carana at Wordpress, November 21, 2011, for discussion and as potential input for a poster for display at AGU 2011 which was also accompanied by a brochure and open letter. The post is added below as an Arctic-news blog page for archival and reference purposes.

A 2008 paper by Shakova et al. considered release of up to 50 Pg of predicted amount hydrate storage as highly possible for abrupt release at any time. Combined amounts of methane from such hotspots of 15 Pg over a short period would result in an immediate burden of 20 Pg of methane (since there already is about 5 Pg in the atmosphere).

What makes things even worse is that this 174 PgC is a global figure, with its impact spread out over the globe, whereas methane from such abrupt releases in the Arctic would – at least initially – be concentrated in the relatively small areas of these hotpots, violently heating up the shallow waters in these areas with the risk of triggering further releases from methane hydrates.

In addition, large releases could cause hydroxyl depletion in the atmosphere, extending the lifetime of methane to decades.

In agreement on the seriousness of this threat, we urge you to tell your Parliamentary Representatives to act as outlined below:

signatories:

Discussion:

Robert W. Howarth et al. and Drew Shindell use a GWP for methane of 105 for 20 years, and 33 for 100 years. That would imply an even higher immediate GWP than 105 over periods less than 20 years.

In its first five years, methane is at least 100 times as potent as carbon dioxide as a greenhouse gas (above image below, from a study by Dessus). Extending the above line would give an immediate GWP of about 120 times that of carbon dioxide.

A 2009 study by Drew Shindell found that increases in global methane emissions did cause a 26% hydroxyl decrease. Because of this, methane now persists longer in the atmosphere, before getting transformed into the less potent carbon dioxide.

A Centre for Atmospheric Science study suggests that sea ice loss may amplify permafrost warming, with an ice-free Arctic featuring a decrease in hydroxyl of up to 60% and an increase of tropospheric ozone (another greenhouse gas) of up to 60% over the Arctic. This lack of hydroxyl means that methane will persist in the atmosphere for longer at its high global warming potency.

Similarly, extension of methane’s lifetime further amplifies its greenhouse effect, especially for releases that are two or three times as large as current releases.

The graph on the right, based on data by Isaksen et al. (2011), shows how methane’s lifetime extends as more methane is released.

The GWP for methane typically includes indirect effects of tropospheric ozone production and stratospheric water vapor production. The study by Isaksen et al. shows (image below) that a scenario of 7 times current methane (image below, medium light colors) over 50 years would correspond with a radiative forcing of 3.6 W/m-2.

Such an increase in methane would thus add more than double the entire current net anthropogenic warming, effectively tripling the effect of all emissions added by people since the industrial revolution (for comparison, see Wikipedia image below).

An addition of less than 30 Pg of methane would create such a scenario (i.e. of 7x the methane we’re used to having in the atmosphere) and this would extend methane’s lifetime to some 18 years, so such a burden will not go away quickly. The situation is even worse when releases take place abruptly over a short period. A single submarine landslide can release 5 Pg of methane, which can double the methane currently in the atmosphere when this occurs in shallow waters, since such a huge release will saturate the water, so most methane will enter the atmosphere unchanged, to trigger further releases.

This kind of warming in the Arctic could result in ever more methane ending up in the atmosphere and remaining there for a longer period without getting oxidized. Initially, all this methane will be concentrated in the arctic, causing huge amplification of the greenhouse effect there in summer, heating up the sea and causing further depletion of oxygen (as algae start to bloom) and further accelerating the permafrost melt and thus causing further carbon to be released from permafrost and clathrates.

Such dramatic local warming is bound to trigger further melting of permafrost locally, resulting in further releases of methane. Massive amounts of methane are stored in the Arctic, much of it concentrated at high density in hydrates. One liter of hydrate can release up to 164 liters of methane. A rise in temperature could cause abrupt releases of huge amounts of methane from hydrates.

Videos

Global temperatures are rising fast. In the Arctic, temperatures are rising even faster (interactive charts below and right). For 2010 and 2011, NASA recorded anomalies of over 2°C at higher latitudes (64N to 90N), with anomalies of over 3°C at latitudes 79N and 81N in 2010.

For November 2010, anomalies of 12.5°C were recorded at latitude 71N, longitude -79 (Baffin Island, Canada). At specific moments in time and at specific locations, anomalies can be even more striking. As an example, on January 6, 2011, temperature in Coral Harbour, located at the northwest corner of Hudson Bay in the province of Nunavut, Canada, was 30°C (54°F) above average.